Coupling for glass fiber connectors with retrofittable security valve

ABSTRACT

A coupling ( 1 ) for receiving at least two plug-in connectors ( 2 ) which are joined to glass fiber cables, comprising at least one moveable cover ( 14 ) which is associated with a sheath opening ( 121 ), said cover covering the opening ( 121 ) of the sheath in a first position, and being able to be moved into a second position by introducing a plug-in connector ( 2 ), whereupon the cover ( 14 ) releases the opening ( 121 ) in the sheath, said cover ( 14 ) comprising a bent metallic leaf spring ( 141 ) and said leaf spring ( 141 ) being unstressed in the first position and the curvature of the leaf spring ( 141 ) being selected in such a way that a ferrule ( 23 ) of the plug-in connector ( 2 ) never comes into contact with the leaf spring ( 141 ) during the insertion process.

The invention relates to a coupling for accommodating plug-in connectors according to the preamble of patent claim 1.

It is known for optical fibers to be connected coaxially to plug-in connectors by means of couplings. The plug-in connectors are designed with a ferrule at the free end for the purpose of central fixing. The two ferules of the plugs which are to be connected can be introduced into a sleeve of the corresponding coupling, the ferrules coming into contact at the end surfaces. The sleeve is mounted in a sleeve mount. The outer shape of the coupling housing is defined by way of the given geometries of a known installation opening. Light waves are transmitted by fiber-optic cables. In order to prevent the emission of harmful laser radiation when the plug is subjected to pulling on one side, a protective device is necessary.

A coupling with a protective device is known, for example, from EP 0 599 784 A1, there being arranged in front of the sleeve opening, as seen in the plug-in direction, a moveable protective flap which, in a closed position, at least partially overlaps the sleeve opening and, in order for the contact pin to be plugged in, can be moved into an open position, the device having an inner bushing housing which can be pushed into an outer bushing housing, and the protective flap being retained, and mounted pivotably, between the two bushing housings. The disadvantage with such a protective device is the amount of space taken up by the pivoting mechanism, with the result that it cannot be realized with small outer dimensions of the coupling. In addition, the high-outlay mechanism is cost-intensive to produce.

The invention is thus based on the technical problem of providing a coupling which is intended for accommodating plug-in connectors connected to fiber-optic cables and which, with small outer dimensions of the coupling, provides protection against the emission of harmful laser radiation and can be produced cost-effectively.

The problem is solved by the subject matter having the features of claim 1. Further advantageous configurations of the invention can be gathered from the subclaims.

The emission of harmful laser radiation from a sleeve opening of a plug receptacle can be prevented by a covering assigned to the same, the covering comprising a bent metallic leaf spring which, in a first, non-loaded position, covers the sleeve opening and, by the introduction of a plug into the plug receptacle, can be moved into a second position, the sleeve opening being free in the second position, and the bending of the leaf spring being selected such that the ferrule does not come into contact with the leaf spring at any point in time during the plug-in operation. The leaf spring is to be selected here such that there is no need for any unnecessary application of force for the plug-in operation, and pronounced loading of the plug on account of the force of the leaf spring in the plugged-in state is avoided. At the same time, the elasticity of the leaf spring ensures that, when the plug is subjected to pulling, reliable return into the non-loaded position takes place. A metallic covering of the sleeve opening is distinguished by good thermal stability. Moreover, the metallic leaf spring allows a very thin configuration of the covering, although the sleeve opening is shielded to good effect. Even colored plastic flaps for covering the sleeve opening require a considerably thicker configuration. In order, in this case, not to obstruct the plug from being accommodated by the covering, a change in the outer shape of the coupling housing is necessary. Changes in the outer shape, however, are undesirable for the purpose of ensuring compatibility with the standard or that further couplings can be added on in a compact manner.

In a preferred embodiment, the covering is formed integrally with a leaf spring and two wings. Via the wings, the covering can be attached tangentially to a housing wall, the movement of the leaf spring being disrupted as little as possible by this attachment. The wings here are limited by the maximum outer dimensions of the coupling.

In one development, the means for accommodating the covering is designed as a separate connection piece which can be connected to the coupling housing. This makes it possible for the connection piece and the coupling housing to be produced separately. This is advantageous since, for example, the material can be selected in accordance with the respective requirements. It is also conceivable for couplings to be used in situations where they do not require any protective device against the emission of laser light. A two-part configuration of the protective device and of the coupling housing allows specific use of the protective device. A single-piece embodiment, however, is more stable and may thus be necessary for specific applications.

In one embodiment, the covering is fastened tangentially to the housing wall by hot stamping. The hot-stamping attachment can be realized cost-effectively. In addition, it is possible to produce the attachment both in the case of a single-piece configuration and in the case of a two-part configuration of the coupling housing and of the connection piece from plastic.

In a preferred embodiment, the connection piece is designed as a plastic part, it being possible for the covering to be connected to the connection piece by injection-molding encapsulation. This makes it possible to realize very good attachment of the covering to the connection piece.

In a further embodiment, the connection piece is designed as a separate sheet-metal part, the covering, configured as a leaf spring, being integrated in the sheet-metal part. Various methods such as spot welding or adhesive bonding are conceivable for attaching the leaf spring to the connection piece. The configuration of the connection piece as a sheet-metal part provides a higher stability than a plastic configuration.

In one development, the connection piece is formed integrally with the covering. This development is distinguished by particular stability.

In a preferred embodiment, the connection piece is attached to the coupling housing by a latching fastening. A latching fastening is advantageous since, on the one hand, automated installation can easily be realized but, on the other hand, it is also possible to provide a releasable connection. This makes it possible for the couplings to be adapted specifically to the respective use.

In a further embodiment, the connection piece is designed, for secure attachment, with centering pins.

The invention is explained in more detail hereinbelow with reference to a preferred exemplary embodiment. In the figures, schematically in each case:

FIG. 1 shows a plan view of a coupling for coaxial optical-fiber connection and of a plug-in connector,

FIG. 2 shows a section through the plan view shown in FIG. 1,

FIG. 3 shows a perspective illustration of a coupling housing and of a connection piece,

FIG. 4 shows a perspective illustration of the connection piece,

FIG. 5 shows a perspective illustration of a covering,

-   -   FIGS. 6(a)-(c) show sectional illustrations of the coupling and         of the plug-in connector during the plug-in operation,

FIG. 7 shows a perspective illustration of a first embodiment of a dust-protection cap, and

FIG. 8 shows a perspective illustration of a second embodiment of the dust-protection cap.

FIG. 1 shows, schematically, a coupling 1 for the coaxial connection of fiber-optic cables. The coupling comprises a coupling housing 10 into which a plug-in connector 2 can be plugged in from each end. The coupling housing 10 is designed with flanges 106, by means of which the coupling 1 can be attached to an installation opening (not illustrated). A connection piece 13 can be latched onto the coupling housing 10. The length of the connection piece 13 may be selected here such that there is no blockage of access to the grip region 22 provided on the plug-in connector 2 in the plugged-in state. The plug-in connector 2 is designed, for assisting guidance in the coupling housing 10, with a tongue 21, which can be introduced into a complementary groove 101 on the coupling housing 10 and into a groove 131 on the connection piece 13.

FIG. 2 shows a section through the coupling 1 and the plug-in connector 2. The designations here correspond to FIG. 1. A sleeve mount 11 with a sleeve 12 is mounted in the coupling housing 10. The plug-in connector 2 is designed with a ferrule 23 at its free end. Two plug-in connectors 2 which are to be connected come into contact in the sleeve 12 via the end surfaces of the ferrules 23, with the result that light waves can be transmitted via the fiber-optic cables formed with the plug-in connectors 2. With a plug-in connector 2 plugged in on one side, the emission of light waves from a sleeve opening 121 has to be prevented. For this purpose, the sleeve opening 121 can be covered via a leaf spring 141. The leaf spring 141 may be selected to be very thin, with the result that, with the plug-in connector 2 placed in position, said spring is in close abutment in a depression of the housing wall and does not obstruct the plug-in connector 2 from being accommodated.

FIG. 3 shows a perspective illustration of the coupling 1. The designations here correspond to FIGS. 1 and 2. The connection piece 13 can be latched onto the coupling housing 10. For the latching fastening, the connection piece 13 is designed with latching tongues 134, which have through-passages 135. The coupling housing 10 is designed, on the contact surfaces 104 of the latching fastening, with latching noses 105, which latch into the through-passages 135. The connection piece 13 does not change the width and depth of the coupling 1, with the result that the tasks of attaching the coupling to a front panel (not illustrated) and of adding on further couplings are not adversely affected. It is also possible, in principle, for the connection piece 13 to be designed with latching noses and the coupling housing 10 to be designed with through-passages.

FIG. 4 shows the connection piece 13 schematically. The designations here correspond to FIGS. 1 to 3. The connection piece 13 may be attached to the coupling housing 10 (not illustrated) by means of centering pins 132, which engage in complementary bores 102 (see FIG. 3) in the coupling housing 10. The through-passages 135 and the complementary latching noses 105 are offset vertically in relation to one another. This makes it possible for the latching noses 105 to be formed straighfforwardly in the coupling housing 10, which is illustrated in FIG. 1. However, other shapes and arrangements of the latching noses 105 are conceivable. It is also conceivable for the latching tongues 134, rather than extending over the entire width of the connection piece 13, only to cover a region around the latching noses 105 in each case. Additional latching fastenings on the two remaining side surfaces are likewise conceivable. However, an additional latching fastening must not conceal the groove 131, which is provided for orienting and/or positioning the plug-in connectors 2, or obstruct the movement of the leaf spring 141, which is provided tangentially to the side surface 136. The latching fastening illustrated, comprising two latching tongues on mutually opposite housing walls, is thus particularly advantageous.

FIG. 5 shows a covering 14 designed with leaf spring 141 and wings 142. The covering 14 is attached to the coupling 1 by means of the wings 142. The size of the wings 142 here is limited by the outer dimensions of the coupling 1. In principle, however, it is also possible for the leaf spring 141 to be attached directly via a tangential extension of the leaf spring.

FIGS. 6(a)-(c) show, schematically, different points in time during a plug-in process. FIG. 6(a) shows the beginning of the plug-in process. At this point in time, the leaf spring 141 is not subjected to loading and covers the sleeve opening 121. The leaf spring 141 is designed with a curvature which, at one end, runs tangentially to the side surface 136. The ferrule 23 of the plug-in connector 2 is worked in a highly precise manner and is thus very sensitive. For this reason and due to a risk of contamination, for example, by metal abrasion, the ferrule 23 must not come into contact with the leaf spring 141 during the plug-in process. The curvature of the leaf spring 141 thus has to be adapted in accordance with the geometry of the plug-in connector 2. FIG. 6(b) shows the displacement of the leaf spring 141 by a relatively wide termination surface 24 of the plug-in connector 2. A sufficient spacing between the ferrule 2 and the leaf spring 141 is ensured here. Laser-beam emission from the coupling housing 10 in the axial direction on account of the sleeve opening 121 being released is prevented by the plug-in connector 2. FIG. 6(c) shows the end of the plug-in operation. The plug-in connector 2 is accommodated in the coupling 1 by latching means. The leaf spring 141 here has been displaced into the depression of the housing wall by the plug-in connector 2. The very thin configuration of the leaf spring 141 causes it to fit very snugly into the depression of the housing wall. Fitting the cover 14 for protection against the emission of laser radiation thus does not require either plug-in connectors 2 provided to be changed or the size of the coupling housing 10 to be increased.

The protective device described only provides protection against the emission of harmful laser radiation. In most cases, this device does not provide sufficient protection against the penetration of dust and other contaminants into the sleeve 12. For additional dust protection when the plug-in connector 2 is subjected to pulling, use has to be made, for example, of a dust-protection cap 3 illustrated in FIG. 7. The dust-protection cap 3 is designed with a cylinder 31 by means of which the cap can be accommodated by the sleeve mount 11, illustrated in FIG. 2 for example, of the coupling 1. In the case of such a dust-protection configuration, the sleeve 12 is sealed precisely at the critical location. The diameter of the cylinder 31 is only dependent on the geometry of the sleeve mount 11, and is thus not dependent on the use of the connection piece 13. The dust-protection cap 3 can be aligned by a tongue 32. The tongue 32 here engages in the groove 101, illustrated in FIG. 1, of a coupling housing 10 and, if a connection piece 13 is used, also in the groove 131. The length of the tongue 32 here does not have to correspond either to the length of the groove 101 or of the grooves 101 and 131, since no sealing is required there. In addition, it is also conceivable to provide dust protection by a cap which seals over the end sides of the coupling housing 10 and/or of the connection piece 13. The advantage with sealing over the end sides is that the entire coupling interior is protected. In order to ensure that the interior is sealed, the groove 101 or the grooves 101 and 131 has/have to be closed by corresponding tongues on the cap. The configuration of the cap is thus no longer dependent on the configuration of the coupling 1, illustrated in FIG. 1, with or without a connection piece 13. That end of the dust protector 3 which is directed away from the coupling 1 is designed with a fixing means 33. Via the fixing means 33, the withdrawn dust-protection cap 3 can be fastened on a cable of a plug-in connector accommodated by the coupling 1. The fixing means 33 comprises a pivotable cover 331, which is designed with a latching hook 334, and a groove 333, which complements the latching hook 334. The latching hook 334 here may be designed such that different latching positions may be assumed when the cover 331 is closed. The fiber-optic cable can be positioned in one of the bores 335 when the cover 331 has been swung open. The bores 335 have different radii, with the result that the dust-protection cap 3 can be fixed on cables with a wide range of different diameters. The outwardly oriented surface 332 of the cover 331 here provides a good inscription surface, which is easily accessible when the coupling 1 is attached to a front panel.

FIG. 8 shows a second embodiment of a fixing means 33 on the dust-protection cap 3. The designations here correspond to FIG. 7. In the second embodiment, the fixing means 33 is designed with a latching connection 34 into which the fiber-optic cable can be latched. The latching connection 34 has bores 341 of different diameters, with the result that they can be plugged onto a multiplicity of different cable diameters. Also conceivable instead of the bores 341 are sawtooth-like formations, by means of which different cables can be fixed and/or clamped in. If the plug-in direction of the latching connection 34 coincides with the axis of the cylinder 41, a possible inscription surface is dispensed with. However, fixing means which allow the inscription surface to be maintained are to be used in preference. The design of the latching connection 34, with a plug-in direction perpendicular to the axis of the cylinder 31, which is illustrated in FIG. 8 is thus advantageous. This second embodiment of the fixing means 33 can be produced in one piece, and thus cost-effectively. The straightforward latching onto a cable is also advantageous. Further embodiments of the fixing means 33, for example fixing on the coupling housing by a chain or a flexible strap or by latching or plugging onto the coupling housing, are likewise conceivable.

Designing the coupling with a protective device according to the invention and with a dust protector means that, when the plug is subjected to pulling, the coupling is protected against the penetration of contaminants and the environment is protected against the emission of laser radiation. The protective device and the dust protector, however, are not mutually dependent.

List of Designations

-   1 Coupling -   10 Coupling housing -   101 Groove -   102 Bore -   104 Contact surface -   105 Latching nose -   106 Flange -   11 Sleeve mount -   12 Sleeve -   121 Sleeve opening -   13 Connection piece -   131 Groove -   132 Centering pin -   134 Latching tongue -   135 Though-passage -   136 Side surface -   14 Covering -   141 Leaf spring -   142 Wing -   2 Plug-in connector -   21 Tongue -   22 Grip region -   23 Ferrule -   24 Termination surface -   3 Dust-protection cap -   31 Cylinder -   32 Tongue -   33 Fixing means -   331 Cover -   332 Inscription surface -   333 Groove -   334 Latching hook -   335 Bore -   34 Latching connection -   341 Bore 

1. A coupling for accommodating at least two plug-in connectors which are connected to fiber-optic cables, comprising at least one moveable covering, which is assigned to a sleeve opening, it being the case that the covering, in a first position, covers the sleeve opening and, by the introduction of a plug-in connector, can be moved into a second position, in which the covering releases the sleeve opening, the covering comprising a bent metallic leaf spring and the leaf spring not being subjected to loading in the first position, wherein the bending of the spring is selected such that a ferrule of the plug-in connection does not come into contact with the leaf spring at any point in time during the plug-in operation, it being the case that the leaf spring, in the second position, rests in a depression of the housing wall, that the coupling is designed at least in two parts with a connection piece and a coupling housing, and that the covering is integrated in the connection piece.
 2. The coupling as claimed in claim 1, wherein the covering is designed with wings or a tangential extension of the leaf spring, be means of which the latter can be fastened tangentially to a side surface of the coupling.
 3. The coupling as claimed in claim 1, wherein the covering is fastened on the coupling by hot stamping.
 4. The coupling as claimed in claim 1, wherein the connection piece is designed as a plastic part, and the covering can be connected to the connection piece by injection-molding encapsulation.
 5. The coupling as claimed in claim 1, wherein the connection piece is designed as a sheet-metal part.
 6. The coupling as claimed in claim 5, wherein the connection piece is formed integrally with the covering.
 7. The coupling as claimed in claim 1, wherein the connection piece is designed with latching means and can be latched onto the coupling housing.
 8. The coupling as claimed in claim 7, wherein the latching means of the connection piece are designed as through-passages in latching tongues and the latching means of the coupling housing are designed as latching noses.
 9. The coupling as claimed in claim 1, wherein the connection between the connection piece and the coupling housing is designed for arresting with centering pins. 